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Probiotics and their potential applications in active edible films and coatings
Probiotics and their potential applications in active edible films and coatings Paula J.P. Espitia, Rejane A. Batista, Henriette M.C. Azeredo, Caio G. Otoni PII: DOI: Reference:
S0963-9969(16)30455-0 doi: 10.1016/j.foodres.2016.10.026 FRIN 6459
To appear in:
Food Research International
Received date: Revised date: Accepted date:
15 June 2016 13 October 2016 16 October 2016
Please cite this article as: Espitia, P.J.P., Batista, R.A., Azeredo, H.M.C. & Otoni, C.G., Probiotics and their potential applications in active edible films and coatings, Food Research International (2016), doi: 10.1016/j.foodres.2016.10.026
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ACCEPTED MANUSCRIPT Probiotics and their potential applications in active edible films and coatings
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Author names
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Paula J. P. Espitiaa*, Rejane A. Batistab, Henriette M. C. Azeredoc, and Caio G. Otonide
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Author affiliations a
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Nutrition and Dietetics School. University of Atlántico - Universidad del Atlántico -.
Puerto Colombia, Atlántico, Colombia (Espitia: [email protected]). b
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Northeast Biotechnology Network (PGP – RENORBIO), Federal University of Sergipe –
São Cristovão, SE 49100-000, Brazil (Batista: [email protected]). Embrapa Tropical Agroindustry – Rua Dra Sara Mesquita, 2270, Fortaleza, CE 60511-
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c
110, Brazil (Azeredo: [email protected]). d
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PPG-CEM, Department of Materials Engineering, Federal University of São Carlos –
Rod. Washington Luís, km 235, São Carlos, SP 13565-905, Brazil (Otoni: [email protected]). e
National Nanotechnology Laboratory for Agribusiness, Embrapa Instrumentation – Rua
XV de Novembro, 1452, São Carlos, SP 13560-979, Brazil.
*Corresponding author: Paula J. P. Espitia, Ph.D. E-mail address: [email protected]; Phone number: +57 301 6323 626
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ACCEPTED MANUSCRIPT ABSTRACT The global market for probiotics has been increasingly growing in recent years guided
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by the rising consumers' demand for healthy diets and wellness. This has caused food
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industries to develop new probiotic-containing food products as well as researchers to study specific characteristics of probiotics as well as their effects on human health.
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Probiotics are defined as live microorganisms that confer a health benefit to the host
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when administered in adequate quantities. Probiotics have been added to several food products as well as incorporated into biopolymeric matrices to develop active food
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packaging as an alternative method for controlling foodborne microorganisms, improving food safety, and providing health benefits. This review includes definition of
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probiotics, description of their effects on human health, discussion on their applications in edible biopolymeric matrices to develop active edible films and coatings, as well as
Keywords:
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the probiotics-related legislation.
probiotic;
food
packaging;
active
packaging;
antimicrobial
activity;
biopolymer; food preservation.
Abbreviations used: CFU, colony-forming units; CMC, carboxymethyl cellulose; COS, chitosan oligosaccharide; EFSA, European Food Safety Authority; EU, European Union; FAO, Food and Agriculture Organization; FOS, fructo-oligosaccharides; GRAS, generally
regarded
as
safe;
GOS,
gluco-oligosaccharides;
GTOS,
galacto-
oligosaccharide; HPMC, hydroxypropyl methylcellulose; MC, methylcellulose; tryptose soy agar; WHO, World Health Organization; WPC, whey protein concentrate.
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ACCEPTED MANUSCRIPT 1. INTRODUCTION Consuming foods with probiotics has increased because of consumer concerns
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regarding healthy diets and wellness. The global market for probiotics – including their
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use as ingredients, supplements, and incorporation in food products – accounted for 14.9 and 16.0 billion US dollars in 2007 and 2008, respectively (Granato, Branco,
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Nazzaro, Cruz, & Faria, 2010). In 2010 and 2011, the global sales of probiotics
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increased to 21.6 and 24.23 billion dollars, respectively. According to the Transparency Market Research, disclosed in 2015, the global market for probiotics was valued at 62.6
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billion dollars in 2014, and is estimated to reach 96.0 billion dollars by 2020. This has aroused the attention of food industries to produce new food products containing
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probiotics as well as researchers who have studied specific characteristics of probiotics and their effects on human health.
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The term probiotic is a relatively new word. It means “for life” and describes bacteria with beneficial effects on humans and animals (FAO, 2001). Indeed, probiotics were originally defined as a “mono- or mixed culture of live micro-organisms which, when applied to man or animal, affects beneficially the host by improving the properties of indigenous microflora” (Huis Veld & Havenaar, 1991). Probiotics are defined by FAO/WHO as “live microorganisms which, when administered in adequate amounts, confer a health benefit to the host” (FAO, 2002). The Japanese definition of probiotics includes cells of nonviable microorganisms that provide health benefits in addition to live microorganisms (Salminen, Ouwehand, Benno, & Lee, 1999). The concept of viability should be used with care as it is defined by most regulatory authorities as culturability, which in turn is highly depended upon culture conditions and media.
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ACCEPTED MANUSCRIPT Reviews have shown positive effects of probiotics at in vivo studies, as well as on human health (Aureli et al., 2011; Clarke, Cryan, Dinan, & Quigley, 2012; Hempel et al.,
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2012; Mattila-Sandholm et al., 1999; Ooi & Liong, 2010; Singh, Kallali, Kumar, &
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Thaker, 2011; Satish Kumar et al., 2015). Probiotics have been incorporated into several food products and supplements, most of them dairy products, such as cheeses,
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dairy desserts, ice-cream, although fermented milks such as yogurts are the most
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popular matrices, which can be obtained from bovine (Batista et al., 2015), caprine (Ranadheera et al., 2012; Ranadheera et al., 2016) and ovine (Balthazar et al., 2016)
matrices are presented in Table 1.
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milk. Recent studies regarding probiotic microorganisms and their applications in food
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The most frequently commercially used bacteria belong to the genera Lactobacillus and
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Bifidobacterium, although Streptococcus thermophilus and Saccharomyces boulardii
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are available in some dairy products (Rastall, Fuller, Gaskins, & Gibson, 2000). Moreover, non-dairy probiotic products have drawn attention due to the growing interest in veganism, as well as to the higher number of consumers with diet restrictions such as lactose intolerance, allergies to milk proteins, and even cholesterol restriction. Hence, non-dairy products (e.g. fruit juices, minimally processed fruits, and fermented vegetables) allow the development of probiotic foods free of cholesterol, lactose and allergens usually found in dairy products (Martins et al., 2013). Alternatively, probiotics may be carried within edible polymer matrices used in the food packaging industry. In this way, probiotics – as well as many other active compounds (Otoni, Espitia, Avena-Bustillos, & McHugh, 2016) – have been incorporated into biopolymeric matrices to develop active/bioactive food packaging materials as an
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ACCEPTED MANUSCRIPT alternative method for controlling pathogenic microorganisms and improving food safety, besides having the potential to favor consumer health. An overview of the
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chronological scenario concerning the investigations on probiotics and on food
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packaging demonstrates that the number of publications on these topics independently has been increasing remarkably throughout the past couple of decades (Figure 1).
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However, to the best of our knowledge, literature on the applications of probiotics in
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active food packaging is scarce, and thus far there is no review article focused solely on this subject. This review highlights the nature of probiotics and their incorporation into
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biopolymer materials intended for active food packaging applications as well as
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legislation related to probiotics.
2. PROBIOTICS: HISTORY, DEFINITION, AND EFFECT ON HUMAN HEALTH
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Ancient civilizations, such as the Greeks and Romans, used fermented dairy foods to maintain health. However, research on microorganisms in fermented food products and their effects on human health have only been studied recently. The history of probiotics started in 1908 when Élie Metchnikoff, Nobel Laureate at the Pasteur Institute, established the relationship between health and longevity with the ingestion of bacteria from yogurt. Dr. Metchnikoff proposed that the bacteria helped control infections caused by enteric pathogens and regulated toxaemia, both of which playing major roles in aging and mortality. This observation resulted in increased yogurt production and consumption (Shah, 2007). The term probiotic has been widely used. According to Hamilton-Miller, Gibson, and Bruck (2003), this term was first used by Lilly and Stillwell in 1965 and referred to
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ACCEPTED MANUSCRIPT observations of in vitro protozoa growth stimulated by other protozoa. During the following decade, the term probiotic was used by Fujii and Cook in 1973 and denoted
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synthetic chemicals in mice that conferred protection against Staphylococcus aureus infection. In 1974, the term was used by Parker in a wider sense to refer to
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microorganism interactions with the animal or human host, i.e. “organisms and
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substances, which contribute to intestinal microbial balance”. Several works concerning
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probiotics have been published since then.
In 2002, FAO/WHO held an expert consultation to evaluate health and nutritional
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properties of probiotics and stablish a definition for probiotics (FAO, 2001). Recently, Wassenaar and Klein (2008) slightly modified the definition to “food or food
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supplements containing defined microorganisms in sufficient numbers to reach the gut
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in viable status resulting in positive health effects after consumption”. The authors claim
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this definition does not contradict the internationally and scientifically accepted definition, although they added qualitative (defined microorganisms) and quantitative (sufficient numbers) requirements to the presumed positive health effects. Probiotic effects are strain specific, thus knowledge of the probiotic genus and species is necessary to obtain the desired effects in the host. The main characteristics of probiotic strains in their relationship with the host are resistance to gastric and bile acid, adherence to mucus or human epithelial cells, antimicrobial activity against pathogenic bacteria, and the ability to reduce pathogen adhesion to surfaces and bile salt hydrolase activity (FAO, 2002). There are several mechanisms by which probiotics may benefit human, including production of antimicrobial substances, strengthening of intestinal barrier, modulation of
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ACCEPTED MANUSCRIPT immune response, and antagonism of pathogenic microorganisms either by production of antimicrobial agents or by competition for binding sites, nutrients, and growth factors
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(FAO, 2001; Marco, Pavan, & Kleerebezem, 2006; Parvez, Malik, Ah Kang, & Kim,
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2006).
When probiotic microorganisms are incorporated into foods, they must be able to
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survive through the digestive tract and successfully proliferate in the gut. Thus, they
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must be resistant to gastric juices and be able to grow in the conditions of the intestine. An interesting option is to use a food matrix that protects them and favors their survival.
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Several factors affect the survival of ingested probiotics in the gastrointestinal tract, including stomach acid, bile salt concentrations, time of exposure, and probiotic species
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and strains. However, many probiotics are able to pass through the gastrointestinal tract and enter the colon in viable numbers in order to impart beneficial effects. In this regard,
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recent studies have explored the effect of the food matrix in the survival of probiotic to the conditions of the gastrointestinal tract and their adhesion to intestinal cells. Ranadheera et al. (2010) have deeply reviewed the relationship among probiotic efficacy and food matrices (and their physicochemical properties), indicating that food matrix selection is a key factor that should be considered when developing functional probiotic food. In this context, Ranadheera et al. (2012) have studied the effect of three different food matrices (goat's milk ice cream, plain and fruit yogurts) on probiotic viability of Lactobacillus acidophilus LA5, Bifidobacterium animalis subsp. lactis BB12 and Propionibacterium jensenii 702, finding that, among the tested food matrices, ice cream presented the best potential to ensure probiotic viability in simulated gastrointestinal conditions (acid and bile tolerance), while fruit yogurt matrix allowed the
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ACCEPTED MANUSCRIPT best cell adhesion of probiotics. Also, probiotic survival to food processing conditions has been studied. In this context, Majeed et al. (2016) studied the survival of Bacillus
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coagulans MTCC 5856 in different functional foods, such as banana muffins and waffles
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for up to 12 months, coffee at extreme conditions (90 °C for 2 min and at 77 °C for 4 h), chocolate fudge frosting, hot fudge top-pings, peanut butter, strawberry and vegetable
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oil at room temperature up to 12 months. As a result, B. coagulans MTCC 5856 showed
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potential to be used as probiotic when developing innovative functional food products due to its stability towards processing and storage condition of tested food.
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Although there is no consensus among the international scientific community about effective probiotic doses to achieve health effects, researchers have suggested
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minimum doses between 106 and 109 CFU·d-1 to ensure therapeutic effects (Espírito Santo, Perego, Converti, & Oliveira, 2011).
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Fermented dairy products are considered good carriers for probiotic microorganisms. Other food matrices, such as fruits and vegetables, are considered potential carriers for these microorganisms because of the increasing lactose intolerance and vegetarianism among consumers (Martins et al., 2013). Besides presenting beneficial health effects, probiotic microorganisms have also been related to effects against other (undesirable) microorganisms when inoculated into foods. In this regard, Alegre, Viñas, Usall, Anguera, and Abadias (2011) tested the antimicrobial activity of a probiotic culture (Lactobacillus rhamnosus GG) against two pathogens – Salmonella and L. monocytogenes. Fresh-cut apple wedges were immersed in solutions containing the probiotic bacteria (10 8 CFU·mL−1) and/or the pathogens (105 CFU·mL−1), placed in polypropylene trays and sealed with a
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ACCEPTED MANUSCRIPT polypropylene plastic film. Results showed that Salmonella was not affected by L. rhamnosus GG, but the population of L. monocytogenes was 1 log cycle lower in the
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presence of the probiotic. The probiotic viability was maintained above recommended
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levels (106 CFU·g-1) until 14 days of storage at 5 °C. Moreover, Fernandes et al. (2013) developed a dairy dessert incorporated with Lactobacillus acidophilus LA-5 as a
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probiotic microorganism and tested its antimicrobial activity against L. innocua by
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means of three formulations (F1: inoculated with L. acidophilus LA-5; F2: inoculated with L. innocua; F3: inoculated with both L. innocua and L. acidophilus LA-5). Differently
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from the results observed by Alegre et al. (2011), the findings by that study showed that the count of the probiotic microorganism diminished while studying product shelf life in
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formulation F1. Also, no antimicrobial effect was observed against L. innocua. In this regard, population of L. innocua increased in formulations F2 and F3, indicating a
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mutual benefit and positive growth effect among the tested probiotic and the target pathogen microorganisms. Similarly, Jesus et al. (2016) studied the interaction of Listeria monocytogenes and probiotic microorganisms (Lactobacillus acidophilus and Bifidobacterium lactis). They reported that L. monocytogenes can growth in probiotic cottage cheese in both condition, when product is submitted to adequate storage conditions (4 °C/ 28 days), as well as in situations of temperature abuse (30% of the shelf life at 4 °C and the remaining 70% at 12 °C). Therefore, microbiological quality of food products incorporated with probiotic microorganisms should not rely on the protective effect of probiotic cultures but on the use of proper hygienic processing conditions and on the excellent microbiological quality of raw materials used.
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3. PROBIOTICS IN ACTIVE/BIOACTIVE EDIBLE FILMS AND COATINGS
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For probiotics to play the intended role in human health, it is essential that both viability
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and the metabolic activity are maintained throughout food processing and supply chain, as well as within human gastrointestinal tract. Several methods have been tested to
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increase the quality of probiotic cultures, including exposure to sub-lethal heat or cold
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stress, osmotic stress, low pH, and reduced redox potential (e.g. through the use of oxygen scavengers, oxygen-consuming microorganisms, and modified atmosphere
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packaging) (Nguyen, Truong, Kouhoundé, Ly, Razafindralambo, & Delvigne, 2016); however, microencapsulation is by far the most exploited approach. When combined,
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microencapsulation and active edible packaging concepts denote a promising strategy
3.1.
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for protecting and delivering probiotic species efficiently.
Microencapsulation of probiotics
Microencapsulation may be defined as the process of packing functional compounds (e.g. probiotic culture) into microcapsules made up of an encapsulant material (da Silva, Barreira, & Oliveira, 2016). When applied to probiotics, microencapsulation techniques are intended to carry and protect them from the detrimental action of pH, oxygen, and light, to mention a few. Therefore, this process can diminish probiotic reactivity to the environment and prevent its degradation, besides masking unpleasant flavors and odors (da Silva et al., 2016). The encapsulation protocols are various, including spray drying (Li et al., 2016; Ranadheera, Evans, Adams, & Baines, 2015), high-voltage electrospinning/electrospraying (Coghetto, Brinques, Siqueira, Pletsch, Soares, & Ayub,
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ACCEPTED MANUSCRIPT 2016; Gomez-Mascaraque, Morfin, Pérez-Masiá, Sanchez, & Lopez-Rubio, 2016), extrusion, spinning disc, vortex bowl, micro nozzle array, impinging aerosol,
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coacervation, and emulsion (Krasaekoopt, 2013). Probiotic encapsulation methods have
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been extensively reviewed elsewhere (de Prisco & Mauriello, 2016; Martín, LaraVilloslada, Ruiz, & Morales, 2015).
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Microencapsulation has been combined to active packaging as an alternative means of
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incorporating probiotics. Probiotic microencapsulation stands out as a promising alternative for applying those microorganisms and replacing antibiotics, since this
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process allows the gradual release of compounds of interest in order to preserve the food (Favaro-Trindade, Pinho, & Rocha, 2008; Mirzaei, Pourjafar, & Homayouni, 2012).
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Thus, studies on the development of active food packaging featuring probiotic microorganism action are worthwhile despite the challenges involved in the
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encapsulation technique itself. Regarding the microencapsulation process, suitable encapsulating materials have been extensively studied, especially biodegradable polymers that can be also applied for active food packaging production. These include alginate (Etchepare et al., 2015; Sohail, Turner, Coombes, Bostrom, & Bhandari, 2011), acetate (Fávaro-Trindade & Grosso, 2002), chitosan (Krasaekoopt, Bhandari, & Deeth, 2003), carboxymethyl cellulose (CMC), protein (Guérin, Vuillemard, & Subirade, 2003; Vonasek, Le, & Nitin, 2014), carrageenan, gelatin, and pectin (Burey, Bhandari, Howes, & Gidley, 2009; Favaro-Trindade et al., 2008; Li et al., 2009). Altamirano-Fortoul, Moreno-Terrazas, Quezada-Gallo, and Rosell (2012) used the combination of microencapsulation and starch-based coatings to incorporate Lactobacillus acidophilus. Those authors coated the surface of partially baked breads with a film-forming solution
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ACCEPTED MANUSCRIPT incorporated with L. acidophilus. According to Altamirano-Fortoul et al. (2012), L. acidophilus remained stable after the baking procedure, presenting counts of 10 7
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CFU·bread-1. Thus, L. acidophilus can be used on bread surfaces by means of microcapsules incorporated in edible coatings, resulting in bread with additional health
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benefits provided by probiotics. L. rhamnosus GG has also been encapsulated in
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hydrogel beads comprising pectin, glucose, and calcium chloride (Li, Zhang, Polk,
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Tomasula, Yan, & Liu, 2016). Moreover, probiotics may also be encapsulated directly into food matrices. In this regard, a mixture of L. acidophilus LA5, Bifidobacterium subsp.
lactis
BB12,
and
Propionibacterium
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animalis
jensenii
702
was
microencapsulated into goats‟ milk (Ranadheera et al., 2015). As a result, the probiotics
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submitted to the encapsulation process maintained satisfactory viable levels (10 6-108 cfu/g); on the other hand, storage conditions at 30 °C after processing reduced
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significantly their viability, while lactobacilli and propionibacteria were not affected when stored at 4 °C.
3.2.
Probiotic edible films and coatings
Increased consumer interest in health, nutrition, food safety, and environmental issues has led to improved research on the film-forming properties of biopolymers to produce edible films for food packaging (Espitia, Du, Avena-Bustillos, Soares, & McHugh, 2013). Although edible films and coatings do not replace an external packaging – which is usually non-biodegradable and, for most probiotic bacteria, must act as a good barrier to oxygen (da Cruz, Faria, & Van Dender, 2007) –, they help packaging in its food protecting function, since they reduce the rates of moisture and gas transfer between
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ACCEPTED MANUSCRIPT food and the surrounding environment, contributing to extend food stability. Edible films may thus reduce the required amount of packaging for each application, reducing the
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negative environmental impact caused by the discard of non-biodegradable materials.
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Apart from their passive protecting function, edible films and coatings may also play some active or bioactive roles.
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The concepts of active and bioactive packaging have been sometimes used
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indiscriminately, but there are differences. Active food packaging systems are those which go beyond the traditional passive role of food protection and include desirable
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interactions with the food, in a way that is relevant to extend food stability; a typical active packaging is antimicrobial packaging, which interacts with the product or the
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headspace inside to decrease, prevent or delay microbial growth on food surfaces (Soares et al., 2009). In previous studies, biopolymers have been used to carry natural
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antimicrobial compounds such as essential oils (Botrel, Soares, Espitia, Sousa, & Renhe, 2010; Espitia, Soares, Botti, & Silva, 2011; Otoni, Avena-Bustillos, Olsen, Bilbao-Sáinz, & McHugh, 2016; Tripathi & Dubey, 2004), organic acids (Schirmer et al., 2009), enzymes (e.g. lysozyme) (Appendini & Hotchkiss, 1997), and bacteriocins (Espitia, Otoni, & Soares, 2016; Gálvez, Abriouel, López, & Omar, 2007; Han, 2005). Active food packaging has been developed in response to consumer demand for safer and less processed food with extended shelf-life (Ahvenainen, 2003). Bioactive food packaging systems, on the other hand, are those which may contribute to health benefits to the consumers (Lopez-Rubio, Gavara, & Lagaron, 2006). It is a novel approach of the concept of functional foods, which proposes that any food that may provide a health benefit beyond the traditional nutrients it contains may be considered
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ACCEPTED MANUSCRIPT as functional. Bioactive packaging materials would thus withhold bioactive agents, which are eventually released into the food product (Lopez-Rubio et al., 2006). In the
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specific case of edible bioactive films and coatings, this release is not even required,
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since the film/coating itself is supposed to be eaten with the food. Bioactive packaging has been reviewed elsewhere (Lopez-Rubio et al., 2006).
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The incorporation of probiotic cultures into edible coatings was first proposed in 2007 by
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Tapia et al. (2007). Thus, research on the development of films and coatings incorporated with probiotics intended as active food packaging is still emerging, with a
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limited number of studies. Edible films and coatings may be regarded as feasible alternatives for carrying and delivering probiotics. Considering that packaging materials
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containing probiotics may enhance food stability (by controlling the growth of spoilage microorganisms by competition) and also contribute to the health of consumers, they
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may be considered both as active and potentially bioactive materials. The main features of the studies on films and coatings containing probiotics are summarized in Table 2.
3.2.1. Studies focused on probiotic viability in films Traditionally, the systems intended to deliver probiotic cultures have both a conventional (pharmaceutical-related products) and a non-conventional (e.g. food-based products) approach (da Silva et al., 2016). Active edible films and coatings may present both aspects as their intake may be expected alongside a regular food product or they may act as exclusively a carrier instead, such as in oral-disintegrating films. Regardless of the mechanism, the major role (i.e. delivering health benefits) of probiotic-containing edible films and coating is played more or less efficiently depending upon their ability to
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ACCEPTED MANUSCRIPT provide viable bacteria to the gastrointestinal tract. The viability, stability, and survival of several probiotic strains under various conditions has been extensively investigated and
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reviewed (Corona-Hernandez, Álvarez-Parrilla, Lizardi-Mendoza, Islas-Rubio, de la
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Rosa, & Wall-Medrano, 2013; Dianawati, Mishra, & Shah, 2016; Paseephol & Sherkat, 2009; Ranadheera et al., 2015; Vinderola, Binetti, Burns, & Reinheimer, 2011). Fewer
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though meaningful studies have focused on evaluating the viability of probiotic strains
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specifically in films in order to assess their stability in terms of active/bioactive properties. These are further discussed in this section.
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Pullulan and various starches (from potato, tapioca, and corn) have been used to develop novel edible films incorporated with a mix of probiotic cultures (Lactobacillus
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reuteri ATCC 55730, L. rhamnosus GG ATCC 53103, and L. acidophilus DSM 20079)
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at an initial concentration of 12.9 log·CFUmL-1 (Kanmani & Lim, 2013). Treatments were
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tested with films prepared from pure pullulan and mixtures of different starches and pullulan, stored at 25 and 4 °C. The probiotic viability in pure pullulan film was around 80% after 10 days of storage at 25 °C, decreasing to 35% after 20 days. Films incorporated with starches, however, presented decreased cell viability: the higher the starch content, the lower the viability. At 4 °C, on the other hand, the viabilities were higher – near 90% for pullulan and pullulan/potato starch (75:25 weight ratio) films up to 30 days of storage. Prebiotics, which may be defined as “the selectively fermented ingredients that allow specific changes, both in the composition and/or activity in the gastrointestinal microbiota that confers benefits upon host well-being and health” (Gibson, Probert, Loo, Rastall, & Roberfroid, 2004), have also been incorporated into edible films to improve
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ACCEPTED MANUSCRIPT the stability of probiotic strains that had been added to the film-forming dispersions. Romano et al. (2014) prepared methylcellulose (MC) films containing two probiotic
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strains (Lactobacillus delbrueckii subsp. bulgaricus CIDCA 333 and Lactobacillus
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plantarum CIDCA 83114) and fructo-oligosaccharides (FOS) as a prebiotic. The bacterial strains were found to be completely embedded in the film matrix, whose
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integrity was not affected by the presence of these probiotic bacteria. Since FOS were
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found to present not only positive effects (protecting L. delbrueckii) but also negative effects (reducing the glass transition temperature of the films), the FOS concentrations
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were selected according to a balance between those effects. Films containing L. delbrueckii were then added with 3% (w/v) of FOS, while films with L. plantarum were
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added with 1% of FOS. L. plantarum was found to be stable for longer periods at higher RH values, when compared to L. delbrueckii, which may be useful for practical
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applications. Similarly, inulin, chitosan oligosaccharide (COS), galacto-oligosaccharide (GtOS) and FOS have been added to maize starch-based edible films for prebiotic purposes and have been shown to promote the growth of the probiotic bacteria Bifidobacterium infantis ATCC 15697 and Lactobacillus fermentum ATCC 9398 (Tang et al., 2015). In addition to the prebiotic effect, these compounds have also affected the physical properties of the edible films, which have shown impaired tensile strength and boosted extensibility when compared to prebiotic-free (control) films. According to the authors, this plasticization effect may be attributed to the much smaller molecular weights of the prebiotics than that of starch. Soukoulis, Behboudi-Jobbehdar, Yonekura, Parmenter, and Fisk (2014) developed gelatin films containing L. rhamnosus GG and four selected prebiotic components:
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ACCEPTED MANUSCRIPT inulin, polydextrose, gluco-oligosaccharides (GOS), and wheat dextrin. The prebiotics made the film structure more uniform. GOS were reported as the prebiotic that provided
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the best protection to the probiotic during film drying at 37 °C, allowing the retention of
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60% of cells, followed by polydextrose, which allowed 26% cell retention during drying. Surprisingly, inulin and wheat dextrin presented a negative effect on bacterial survival.
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On the other hand, inulin was the most effective prebiotic agent to protect the probiotic
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during storage; while it took 63–83 days for the films with other prebiotics to have their probiotic population reduced by 1 log cycle, the same reduction occurred after 100 days
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for the film with inulin.
Starch (from rice and corn)-protein (bovine gelatin, sodium caseinate, and soy protein)
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edible films were added by L. rhamnosus GG and stored at fridge and room temperature (Soukoulis, Singh, Macnaughtan, Parmenter, & Fisk, 2016). Both storage
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temperature and film composition were found to play a significant role in the viability and stability of the probiotic culture during the film-forming procedure as well as throughout storage. The loss of L. rhamnosus GG cells induced by film processing (i.e. solvent evaporation), for instance, was significantly lower in protein-based films than in their starch-based counterparts. Furthermore, rice starch and proteins were observed to act synergistically as to L. rhamnosus GG viability. Finally, film shelf life (threshold: 6 log viable CFU·g-1) was maintained until 27-96 and 15-24 days when stored at 4 and 25 °C, respectively (Soukoulis et al., 2016). Piermaria, Diosma, Aquino, Garrote, and Abraham (2015) incorporated L. plantarum and Kluyveromyces marxianus cells into glycerol-plasticized edible kefiran (a polysaccharide produced by lactic acid bacteria) films. While the authors demonstrated
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ACCEPTED MANUSCRIPT that the physical and optical properties of the films were nearly unchanged upon the addition of the probiotic cultures, the high susceptibility of the latter to acid was reduced
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by its inclusion into the polymer matrix. The film-forming procedure (casting at 37 °C)
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led to a slight decrease in the L. plantarum count, whereas that of the yeast remained constant. Furthermore, the viability of both microorganisms was maintained throughout
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storage at non-refrigerated temperature.
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Coatings based on sodium alginate or alginate/whey protein concentrate (WPC) containing L. rhamnosus GG have been applied by Soukoulis, Yonekura et al. (2014) to
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bread, which was then air dried at 60 °C for 10 min or 180 °C for 2 min. The alginate/WPC coating resulted in higher viability of the probiotic strain throughout drying
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(76.3%) when compared to the alginate coating (15.9%), while the drying regime did not significantly affect the viability. The cell viability was considerably reduced during the
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initial 24 h of storage, then stabilized, and finally increased upon days 4-7 of storage. Differently from most other studies, this one included an in vitro digestion test for evaluating probiotic viability, and also defined the amount of probiotics to be delivered with a certain amount of food. Coated bread crust samples were submitted to in vitro digestion under simulated gastrointestinal conditions; the sample coated with alginate resulted in a lower viability loss (0.7 log CFU·g-1) than the sample coated with alginate/WPC (1.5–1.6 log CFU·g-1), that is to say, the alginate coating provided higher protection than alginate/WPC coating upon in vitro digestion. The probiotic level to be delivered by a bread slice (30–40 g) was calculated as being 7.6–9 log CFU (before digestion) and 6.5–6.9 log CFU (after in vitro digestion), meeting the required cell counts for the bread to be considered as probiotic.
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3.2.2. Studies focused on inhibitory activity against other microbial species
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Tapia et al. (2007) applied alginate and gellan edible coatings incorporated with B. lactis
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BB-12 on fresh-cut fruits (apple and papaya cylinders). Alginate or gellan film-forming solutions (2% w/v) incorporated with viable bifidobacteria were applied on the surface of
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the fresh-cut fruits. The results showed that, even if the counting of B. lactis Bb-12 in
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coatings usually decreased significantly upon 10 days of storage at 2 °C (with viability losses of up to 85%), it was still greater than 106 CFU·g-1 after 10 days. These results
a viable manner on fresh-cut fruits.
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indicated that alginate and gellan are able to carry and hold probiotic microorganisms in
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Gialamas, Zinoviadou, Biliaderis, and Koutsoumanis (2010) developed edible films from sodium caseinate incorporated with Lactobacillus sakei cells. Two techniques were
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used to add the probiotic strain into the caseinate matrix – i.e. direct incorporation to the film-forming solution or spraying on a pre-formed film. The films were applied to the surface of both a laboratory medium (tryptose soy agar, TSA) and a food model system (fresh beef) previously inoculated with L. monocytogenes. After the contact of the film with the surface of TSA at 4 °C, the population of L. sakei grew rapidly, from an initial population of less than 106 to 107 CFU·cm-2 within 4 days, regardless of the L. sakei addition technique. After 12 days of storage, films containing L. sakei presented a pathogen population decreased by 3 log cycles (in the case of films obtained from the probiotic-containing film-forming solution) or 3.6 log cycles (in the case of the sprayed film). The L. monocytogenes level in fresh beef packed in films containing L. sakei and stored at 4 °C was reduced by 2 log cycles when compared to the samples with the
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ACCEPTED MANUSCRIPT control film (without L. sakei). The counting of L. sakei was maintained above 106 CFU·cm-2 of film area for at least 21 days at 4 °C. Interestingly, sorbitol (used as a film
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plasticizer) was found to improve the viability of L. sakei, corroborating the role of
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polyols as protective agents for microbial cells upon storage at low water activity (Linders, de Jong, Meerdink, & van't Riet, 1997). Some mechanisms have been
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proposed to explain these protective effects, such as lowering the phase transition
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temperature of dry membranes, maintaining the membrane fluidity, and protecting the protein structure in dry state (Leslie, Israeli, Lighthart, Crowe, & Crowe, 1995;
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Santivarangkna, Naumann, Kulozik, & Foerst, 2010). Carnobacterium maltaromaticum is considered as a potential probiotic microorganism
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(Lauzon et al. 2014), commonly found in several fish species as part of their normal intestinal flora. C. maltaromaticum isolated from rainbow trout (Oncorhynchus mykiss)
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presented activity against Gram-positive and Gram-negative pathogens, as well as a broad spectrum of antibiotic resistance (Kim & Austin, 2008). Concha-Meyer, Schöbitz, Brito, and Fuentes (2011) developed a film based on alginate incorporated with viable C. maltaromaticum to preserve smoked salmon at refrigeration temperatures. The films were applied on the surface of smoked salmon pieces and presented bacteriostatic effect against L. monocytogenes – which had been previously inoculated to a final concentration of 104 CFU·cm-2 – over 28 days at 4 °C. The authors indicated that these results exceed the industrial shelf-life requirements for smoked salmon, demonstrating that the developed films inhibited L. monocytogenes on salmon under specified conditions.
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ACCEPTED MANUSCRIPT The probiotic bacteria L. acidophilus and Bifidobacterium bifidum were inoculated into edible gelatin coatings and films for preserving hake fish (Merluccius merluccius) (López
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de Lacey, López-Caballero, Gómez-Estaca, Gómez-Guillén, & Montero, 2012). The counts of L. acidophilus and B. bifidum, both on film-forming solutions and films
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presented an initial concentration of 109 CFU·mL-1, with both probiotic cultures
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remaining constant for 6 days at 2 °C. The application of gelatin coatings (with or
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without B. bifidum) to hake cuts resulted in a significant reduction of the population of H2S-producing microorganisms, presumably Shewanella putrefaciens, when compared
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to the uncoated hake. Thus, the study was not conclusive about whether the reduction in the growth of H2S-producing microorganisms resulted from an inhibitory effect from
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the probiotic bacteria or from the coating itself. In a second step of the study, hake wrapped with films were submitted to a low-level high pressure treatment (200 MPa for
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10 min at 20 °C), in order to reduce the Gram-negative flora while affecting less the Gram-positive bacteria (including those incorporated in the film), and also to avoid sensory changes of fish. The counts of total bacteria and H2S producers were reduced by the high pressure treatment, while both counts of lactic acid bacteria and bifidobacteria were unaffected by it. The results suggest that the combination of edible films containing bifidobacteria with a high pressure treatment is promising for the preservation of fish and other products whose spoilage is determined by Gram-negative bacteria. The same group conducted another study (López de Lacey, López-Caballero, & Montero, 2014) incorporating green tea extract and two probiotic strains (Lactobacillus paracasei L26 and B. lactis B94) into agar-based films that were then applied to hake
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ACCEPTED MANUSCRIPT fillets previously inoculated with S. putrefaciens and Photobacterium phosphoreum (103–104 CFU·g-1). The probiotic bacteria migrated to the fish, resulting in proliferation of
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lactic acid bacterial populations. The films containing probiotics and/or green tea extract
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resulted in decreased chemical spoilage indicators (total volatile bases and trimethylamine nitrogen, and pH changes) and reduced counts of H 2S-producing
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microorganisms, when compared to hake coated with a film without those agents or
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uncoated hake. The combination of probiotics with green tea extract in films resulted in better chemical and microbial stabilities when compared to films containing just
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probiotics, leading to a shelf-life extension of at least a week. Different biopolymers, such as sodium caseinate, pea protein, MC and hydroxypropyl
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methylcellulose (HPMC), have been tested for incorporating L. plantarum in edible films based on polysaccharide or protein (Sánchez-González, Quintero Saavedra, & Chiralt,
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2013). According to Sánchez-González et al. (2013), protein-based films allowed higher L. plantarum viability, with bacteriocin production being slower than in cellulose-based films, which in turn presented higher bacteriocin production. In addition, HPMC and MC films incorporated with L. plantarum completely inhibited Listeria innocua growth during the first 8 days of storage at 5 °C, indicating that these films were effective carriers of L. plantarum. Sodium caseinate and MC have been used to develop biopolymeric films incorporated with L. acidophilus and L. reuteri (Sánchez-González, Quintero Saavedra, & Chiralt, 2014). The survival of both probiotic cultures in biopolymeric films and their antimicrobial potential against L. innocua were assessed. Sánchez-González et al. (2014) reported that the viability of L. acidophilus was greater than that of L. reuteri in
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ACCEPTED MANUSCRIPT both polymeric matrices. L. reuteri presented a significant reduction of its initial population during the first week of storage, indicating that this strain is more sensitive to
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the stress suffered during storage. Moreover, when comparing both hydrocolloid matrices, sodium caseinate was a more favorable environment than MC for
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microorganism survival, reaching viability on the order of 10 7 CFU·cm-2 after 3 days of
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storage. With regard to the antilisterial activity, the best results were obtained with MC
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films after 3 days of storage. No differences were observed among the different films after a longer storage time, though L. innocua growth was reduced by approximately 1.5
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log cycles compared to the control after 12 days of storage.
applications
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3.3 Food matrix consideration and potential for probiotic films and coatings
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Traditionally, dairy food products have been used as carriers of probiotic microorganisms. Recently, other food matrices with a different origin have been tested with the same purpose, such as meat, traditional cereal-based beverages and chocolate (Figure 3).
The physicochemical as well as functional properties of these food matrices have a key role in ensuring probiotic viability. In this regard, Ranadheera et al. (2010) have indicated that food formulation can be used to favor probiotic viability, with concentration of fat, protein, carbohydrates and their interactions as the main factors that support probiotic microbial growth. Thus, properly formulated food can be an effective carrier of probiotic by two means:
Direct probiotic delivery through the formulated food matrix;
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Indirect probiotic delivery, when formulated food constitutes the polymeric matrix for packaging material development. In this context, the developed packaging material
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is edible and should present satisfactory conditions for probiotic viability.
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Moreover, food preservation is commonly associated with chemical additive and good manufacturing and storing practices. However, active food packaging incorporated with
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natural compounds has emerged as a potential alternative to chemical preservative for
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food preservation. Previous research studies (Tapia et al. 2007; Gialamas et al. 2010; Concha-Meyer et al. 2011; López de Lacey et al. 2012; López de Lacey et al. 2014;
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Soukoulis et al. 2014b) have shown the potential food that might be preserved by the application of probiotic films and coatings include fish, fresh meat, fruits and baked food
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products, such as bread (Figure 2).
In any case, whether the probiotic is incorporated into the formulated food or into the
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packaging material, the carrier should protect probiotic microorganisms against external factors, as well as the effect of the gastrointestinal and bile conditions (Desobry & Debeaufort (2012).
4. REGULATIONS RELATED TO PROBIOTICS AND ACTIVE FOOD PACKAGING In the United States, regulatory requirements are determined by the intended use of probiotics, whether as a drug or as a dietary supplement. Although probiotics fall into virtually all product categories regulated by the FDA, there is still no pathway to deal specifically with probiotics. Instead, probiotic products are regulated based on the product category into which they fall, such as food or food additive (Hoffmann et al., 2012, reviewed in 2016; U.S. Food and Drug Administration, 2016). For example, only
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ACCEPTED MANUSCRIPT premarket notification is required if the probiotic product is intended to be used as a dietary supplement (Venugopalan, Shriner, & Wong-Beringer, 2010). The probiotic
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product must go through a regulatory process, however, if the probiotic is intended to be
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used as a drug.
Most probiotic microorganisms have a long-lasting history of safe use as food
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components, so safety evaluation does not denote a hurdle to be overcome (van
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Loveren, Sanz, & Salminen, 2012). Among them, numerous microorganisms have been qualified with the presumption of safety (QPS) status for food applications (EFSA, 2010;
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Leuschner et al., 2010) by the European Food Safety Authority (EFSA) and have been
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Administration (FDA, 2016).
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classified as generally regarded as safe (GRAS) by the U.S. Food and Drug
On the other hand, the European legislation is more conservative, as described by
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Miquel et al. (2015) and Glanville, King, Guarner, Hill, & Sanders (2015). The term “probiotic” is not regulated, since the designation implies a beneficial health effect, and should be considered a health claim by itself. On one hand, many microorganisms currently used in food fermentation have a long history of safe use in the European Union (EU). On the other hand, foods containing microorganisms which have not had a traditional use in food production in Europe before 1997 are considered as novel foods, whose legislation is currently under Regulation (EC) No 2015/2283 (European Commission, 2015). A novel food should be subjected to an in-depth characterization and safety assessment should be done before commercialization on the European market. According to the EU legislation on health claims, based on Regulation (EC) No 2006/1924 (European Commission, 2006), the communication of any health claim to
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ACCEPTED MANUSCRIPT consumers (such as categorizing a food product as “probiotic”) may only be made after authorization by the European Commission, which requires a favorable opinion from the
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EFSA. In Brazil, the “Technical regulation of bioactive substances and probiotics isolates with
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alleged of functional or health properties” (RDC No 2/2002 ANVISA) is used as a
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guideline for the safety assessment, registration and commercialization of bioactive
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substances and probiotics with claims of health properties (ANVISA, 2002). However, Brazilian regulation, similar to those of USA and Europe, does not provide a specific law
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5. FINAL CONSIDERATIONS
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for edible materials containing probiotic microorganisms.
The global probiotics market has been constantly growing due to consumer concerns
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regarding healthy diets and wellness. In this context, the consumption of probiotic food products has been constantly increasing. Another trend in food technology is the growing use of edible films and coatings, acting as packaging aids towards extending food stability.
Incorporating probiotics into edible films and coatings has been proposed as an emerging technology which has generated a number of studies in the last decade. The probiotic films and coatings would be considered as bioactive materials, in the sense that they may promote health benefits to the consumer, due to their potential probiotic properties. Concomitantly, probiotic films and coatings may also be considered as active, in the sense that they may promote an active role in extending food stability, which is based on the premise that probiotic bacteria present competitive effects against
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ACCEPTED MANUSCRIPT spoilage microorganisms. However, although the incorporation of probiotic bacteria into an edible material is expected to be primarily motivated by the promotion of health
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benefits to the consumers, those effects have not been approached in those studies.
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Instead, developed studies were focused on either evaluating the viability of the probiotic strains (in order to establish if the films are suitable to keep the probiotics alive
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throughout processing and storage) and/or studying the effects of films or coatings on
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growth of spoiling or pathogenic microorganisms, based on the premise that probiotic bacteria present competitive effects against spoilage bacteria. Just one study
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(Soukoulis, Yonekura, et al., 2014) advanced in evaluating cell viability upon simulated gastrointestinal conditions, and also established the level of probiotic to be delivered by
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a defined portion of the food product. Nevertheless, more studies are required to evaluate two important aspects of any product to be considered as probiotic: (a) the
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ability of probiotic strains contained in edible films or coatings to survive the transit through the upper gastrointestinal tract, and (b) the release of probiotic strains from the matrices to colonize the intestine. Those kinds of information are essential to establish whether the materials may really be regarded as probiotic edible films and coatings, or just active materials with antimicrobial effects to extend food stability.
6. ACKNOWLEDGEMENTS PJP Espitia thanks the National Bureau for the Development of Science and Technology in Colombia (COLCIENCIAS) and Universidad del Atlántico. RA Batista thanks the support provided by National Counsel of Technological and Scientific
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ACCEPTED MANUSCRIPT Development (CNPq). CG Otoni thanks the financial support of São Paulo Research
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Foundation (FAPESP, grant # 2014/23098-9).
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ACCEPTED MANUSCRIPT Figure captions Figure 1. Number of publications on probiotics (topic: probiotic*) and on food packaging
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Figure 2. Direct probiotic delivery through the formulated food matrix.
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Table 1. Recent studies regarding probiotic applications in food matrices Probiotic Food Research target Reference microorganism matrix Streptococcus thermophiles salivarius spp. TA 040 Evaluation of quality parameters of Lactobacillus delbrueki strawberry probiotic yogurt added with Batista et al spp. bulgaricus LB340 glucose oxidase. To do so, developed 2015 Lactobacillus product was compared with commercial acidophilus La14 probiotic products. Bifidobacterium longum BL05 Streptococcus thermophilus TA040 Lactobacillus delbrueckii ssp. Incorporation of glucose oxidase in Cruz et al bulgaricus LB340 increasing levels and its effect in the 2012 Yogurt Bifidobacterium developed final product. longum BL05 Lactobacillus acidophilus LA14 Lactobacillus acidophilus LA5 Assessment of the viability of tested Bifidobacterium probiotic microorganisms in plain and Ranadheera animalis subsp. lactis stirred fruit yogurts based on goats‟ milk, et al 2012 BB12 as well as product characteristics Propionibacterium (physicochemical and sensorial). jensenii 702 Streptococcus thermophiles Evaluation of the physicochemical Balthazar et Lactobacillus parameters of sheep yogurt containing al 2016 delbrueckii ssp. inulin at different concentrations. bulgaricus Lactobacillus Evaluation of the efficiency of two different acidophilus LA14 Yogurt probiotic matrices on the immune system Lollo et al Bifidobacterium and whey in Wistar rats exercised to the point of 2013 longum BL05 beverage exhaustion after receiving the developed products for 14d. Streptococcus Evaluation of the efficiency of the salivarius thermophilus developed product submitted to ultra-high ssp. TA040 temperature and dynamic high pressure in Lollo et al Fermented maintaining the immune system of rats Lactobacillus 2015-2 milk acidophilus NFCM exercised to exhaustion after receiving the product for 14d. Streptococcus Determination of the influence of dynamic Oliveira et high pressure on the probiotic developed 52
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Development of a fermented dairy drink based on goats‟ milk and incorporated with Lactobacillus acidophilus LA5, Fermented Bifidobacterium animalis subsp. lactis dairy drink Ranadheera BB12 and Propionibacterium jensenii 702, made from et al. 2016 alone or in combination; and goats‟ milk determination of main developed product characteristics (microbial, physicochemical, and sensorial). Evaluation of the L. casei Zhang incorporation on main characteristics Dantas et al (physicochemical, optical, rheological and 2016 sensorial) of the developed product. Determination of the sodium reduction and Felicio et al arginine incorporation effect on quality 2016 parameters of the developed product. Assessment of increasing concentration of probiotic microorganisms on Gomes et al Minas physicochemical parameters and sensory 2011 fresh acceptance of developed product. cheese Evaluation of key parameters of the immune system of Wistar rats that were Lollo et al submitted to acute, intense physical 2012 exercise after receiving a diet with the developed product for 14d. Assessment of the effect of developed product consumption on arterial Lollo et al hypertension parameters while tested in 2015 spontaneous hypertensive rats (SHRs, 7 weeks old). Assessment of the ideal sucrose concentration and other sweeteners (stevia, sucralose, aspartame, and Esmerino et Neotame on the viability of the starter and al 2013 Petit probiotic cultures while incorporated in the Suisse developed product. cheese Estimation of the optimum sucrose concentration and predictions of optimum Esmerino et sucrose level based on acceptance testing al 2015 of the developed product.
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Lactobacillus acidophilus LA-5
product.
Reference
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Lactobacillus acidophilus LA5
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Food matrix
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Probiotic microorganism thermophilus TA40 Lactobacillus acidophilus NFCM® Lactobacillus acidophilus LA5 Bifidobacterium animalis subsp. lactis BB12 Propionibacterium jensenii 702
Lactobacillus acidophilus LA14 Bifidobacterium longum BL05 Lactobacillus acidophilus LA14 Bifidobacterium longum BL05
Lactobacillus acidophilus LA14 Bifidobacterium lactis BL04
Lactobacillus acidophilus Bifidobacterium lactis
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Research target
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Evaluation of the effect of antioxidants compounds on the physicochemical, rheological and sensory characteristics of developed product.
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Assessment of the performance of the jabuticaba skin extract in minimizing the oxidative stress in the developed product.
Reference
Pereira et al 2016
Pereira et al 2016-2
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Probiotic microorganism Lactobacillus acidophilus LAC4 Bifidobacterium animalis ssp. lactis DN173–010 Lactobacillus acidophilus LAC4 Bifidobacterium animalis sub sp. lactis DN173-010
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ACCEPTED MANUSCRIPT Table 2. Bioactive films and coatings containing probiotic bacteria Viability
B. lactis Bb12
-
Coatings on fresh-cut apples and papayas
> 6 log cycles CFU·g up to 10 days at 2 °C
-
Films on fresh beef
> 6 log cycles CFU·cm up to 21 days at 4 °C
-2
L. sakei
> 7 log cycles CFU·cm up to 28 days at 4 °C
-2
C. maltaromati cum L. acidophilus B. bifidum
Films on smoked salmon Films and coatings on hake fish
-
-
Green tea extract
Films on hake fillets
Methylcellulo se
L. delbrueckii L. plantarum
Prebiotic: FOS
Films, no substrate
Pullulan Pullulan/starc h blends
L. rhamnosus,, L. reuteri, L. acidophilus
Alginate Alginate/whe y protein concentrate Hydroxyprop yl methylcellulo se Isolate pea protein Methylcellulo se Sodium caseinate Methylcellulo se (MC)
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Gelatin
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Agar
L. paracasei B. lactis
Films, no substrate
> 8 log cycles CFU·g up to 6 days at 2°C
> 6 log cycles CFU·cm up to 15 days at 4 °C
-2
Time for 1 log reduction (11% RH, 4 °C): L. delbrueckii, 45 days; L. plantarum, 90 days Highest viabilities for pullulan and pullulan/potato starch (75:25): near 90% viability up to 30 days at 4 °C.
Films, no substrate
Time for 1 log reduction (4 °C): 63 days (glucooligosaccharides) to 100 days (inulin)
-
Coatings on bread
-
(a)
L. monocytog enes L. monocytog enes
(b)
(c)
L. plantarum
L. reuteri L.
-
(d)
H2Sproducing microorgan isms
(e)
-
(f)
-
(g)
-
(h)
> 10 CFU·g up to 7 days at room temperature.
-
(i)
Glycerol
Films, no substrate
Highest viabilities for 5 sodium caseinate: > 10 -2 CFU·cm up to 30 days at 5 °C.
L. innocua
(j)
Glycerol
Films, no substrate
Highest viabilities for L. 4 Acidophilus: > 10
L. innocua
(k)
6
L. rhamnosus
Refere nce*
-1
Prebiotics: inulin, polydextro se, glucoseoligosacch arides, wheat dextrin
L. rhamnosus
Inhibition of other species -1
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Caseinate
Gelatin
Substrate
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Alginate Gellan
Alginate
Other additives
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Probiotic
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Biopolymeri c matrix
-1
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ACCEPTED MANUSCRIPT acidophilus
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(sodium caseinate) and 3 -2 > 10 (MC) CFU·cm up to 30 days at 5 °C. *Cited references: (a): Tapia et al. (2007); (b): Gialamas et al. (2010); (c) Concha-Meyer et al. (2011); (d) López de Lacey et al. (2012); (e) López de Lacey et al. (2014); (f) Romano et al. (2014); (g) Kanmani and Lin (2013); (h) Soukoulis et al. (2014a); (i) Soukoulis et al. (2014b); (j) Sánchez-González et al. (2013); (k) Sánchez-González et al. (2014).
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Sodium caseinate
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ACCEPTED MANUSCRIPT
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Graphical abstract
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ACCEPTED MANUSCRIPT
Highlights
Researchers have been developing new food products containing probiotics
Probiotics are incorporated into polymeric matrices for food packaging purposes
Edible films and coatings incorporated with probiotics are reviewed
Probiotic food packaging is an alternative for controlling foodborne pathogens
Probiotic packaging improves food safety and provides health benefits
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S0963-9969(16)30455-0 doi: 10.1016/j.foodres.2016.10.026 FRIN 6459
To appear in:
Food Research International
Received date: Revised date: Accepted date:
15 June 2016 13 October 2016 16 October 2016
Please cite this article as: Espitia, P.J.P., Batista, R.A., Azeredo, H.M.C. & Otoni, C.G., Probiotics and their potential applications in active edible films and coatings, Food Research International (2016), doi: 10.1016/j.foodres.2016.10.026
This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Probiotics and their potential applications in active edible films and coatings
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Author names
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Paula J. P. Espitiaa*, Rejane A. Batistab, Henriette M. C. Azeredoc, and Caio G. Otonide
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Author affiliations a
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Nutrition and Dietetics School. University of Atlántico - Universidad del Atlántico -.
Puerto Colombia, Atlántico, Colombia (Espitia: [email protected]). b
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Northeast Biotechnology Network (PGP – RENORBIO), Federal University of Sergipe –
São Cristovão, SE 49100-000, Brazil (Batista: [email protected]). Embrapa Tropical Agroindustry – Rua Dra Sara Mesquita, 2270, Fortaleza, CE 60511-
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c
110, Brazil (Azeredo: [email protected]). d
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PPG-CEM, Department of Materials Engineering, Federal University of São Carlos –
Rod. Washington Luís, km 235, São Carlos, SP 13565-905, Brazil (Otoni: [email protected]). e
National Nanotechnology Laboratory for Agribusiness, Embrapa Instrumentation – Rua
XV de Novembro, 1452, São Carlos, SP 13560-979, Brazil.
*Corresponding author: Paula J. P. Espitia, Ph.D. E-mail address: [email protected]; Phone number: +57 301 6323 626
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ACCEPTED MANUSCRIPT ABSTRACT The global market for probiotics has been increasingly growing in recent years guided
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by the rising consumers' demand for healthy diets and wellness. This has caused food
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industries to develop new probiotic-containing food products as well as researchers to study specific characteristics of probiotics as well as their effects on human health.
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Probiotics are defined as live microorganisms that confer a health benefit to the host
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when administered in adequate quantities. Probiotics have been added to several food products as well as incorporated into biopolymeric matrices to develop active food
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packaging as an alternative method for controlling foodborne microorganisms, improving food safety, and providing health benefits. This review includes definition of
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probiotics, description of their effects on human health, discussion on their applications in edible biopolymeric matrices to develop active edible films and coatings, as well as
Keywords:
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the probiotics-related legislation.
probiotic;
food
packaging;
active
packaging;
antimicrobial
activity;
biopolymer; food preservation.
Abbreviations used: CFU, colony-forming units; CMC, carboxymethyl cellulose; COS, chitosan oligosaccharide; EFSA, European Food Safety Authority; EU, European Union; FAO, Food and Agriculture Organization; FOS, fructo-oligosaccharides; GRAS, generally
regarded
as
safe;
GOS,
gluco-oligosaccharides;
GTOS,
galacto-
oligosaccharide; HPMC, hydroxypropyl methylcellulose; MC, methylcellulose; tryptose soy agar; WHO, World Health Organization; WPC, whey protein concentrate.
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ACCEPTED MANUSCRIPT 1. INTRODUCTION Consuming foods with probiotics has increased because of consumer concerns
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regarding healthy diets and wellness. The global market for probiotics – including their
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use as ingredients, supplements, and incorporation in food products – accounted for 14.9 and 16.0 billion US dollars in 2007 and 2008, respectively (Granato, Branco,
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Nazzaro, Cruz, & Faria, 2010). In 2010 and 2011, the global sales of probiotics
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increased to 21.6 and 24.23 billion dollars, respectively. According to the Transparency Market Research, disclosed in 2015, the global market for probiotics was valued at 62.6
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billion dollars in 2014, and is estimated to reach 96.0 billion dollars by 2020. This has aroused the attention of food industries to produce new food products containing
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probiotics as well as researchers who have studied specific characteristics of probiotics and their effects on human health.
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The term probiotic is a relatively new word. It means “for life” and describes bacteria with beneficial effects on humans and animals (FAO, 2001). Indeed, probiotics were originally defined as a “mono- or mixed culture of live micro-organisms which, when applied to man or animal, affects beneficially the host by improving the properties of indigenous microflora” (Huis Veld & Havenaar, 1991). Probiotics are defined by FAO/WHO as “live microorganisms which, when administered in adequate amounts, confer a health benefit to the host” (FAO, 2002). The Japanese definition of probiotics includes cells of nonviable microorganisms that provide health benefits in addition to live microorganisms (Salminen, Ouwehand, Benno, & Lee, 1999). The concept of viability should be used with care as it is defined by most regulatory authorities as culturability, which in turn is highly depended upon culture conditions and media.
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ACCEPTED MANUSCRIPT Reviews have shown positive effects of probiotics at in vivo studies, as well as on human health (Aureli et al., 2011; Clarke, Cryan, Dinan, & Quigley, 2012; Hempel et al.,
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2012; Mattila-Sandholm et al., 1999; Ooi & Liong, 2010; Singh, Kallali, Kumar, &
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Thaker, 2011; Satish Kumar et al., 2015). Probiotics have been incorporated into several food products and supplements, most of them dairy products, such as cheeses,
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dairy desserts, ice-cream, although fermented milks such as yogurts are the most
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popular matrices, which can be obtained from bovine (Batista et al., 2015), caprine (Ranadheera et al., 2012; Ranadheera et al., 2016) and ovine (Balthazar et al., 2016)
matrices are presented in Table 1.
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milk. Recent studies regarding probiotic microorganisms and their applications in food
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The most frequently commercially used bacteria belong to the genera Lactobacillus and
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Bifidobacterium, although Streptococcus thermophilus and Saccharomyces boulardii
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are available in some dairy products (Rastall, Fuller, Gaskins, & Gibson, 2000). Moreover, non-dairy probiotic products have drawn attention due to the growing interest in veganism, as well as to the higher number of consumers with diet restrictions such as lactose intolerance, allergies to milk proteins, and even cholesterol restriction. Hence, non-dairy products (e.g. fruit juices, minimally processed fruits, and fermented vegetables) allow the development of probiotic foods free of cholesterol, lactose and allergens usually found in dairy products (Martins et al., 2013). Alternatively, probiotics may be carried within edible polymer matrices used in the food packaging industry. In this way, probiotics – as well as many other active compounds (Otoni, Espitia, Avena-Bustillos, & McHugh, 2016) – have been incorporated into biopolymeric matrices to develop active/bioactive food packaging materials as an
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ACCEPTED MANUSCRIPT alternative method for controlling pathogenic microorganisms and improving food safety, besides having the potential to favor consumer health. An overview of the
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chronological scenario concerning the investigations on probiotics and on food
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packaging demonstrates that the number of publications on these topics independently has been increasing remarkably throughout the past couple of decades (Figure 1).
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However, to the best of our knowledge, literature on the applications of probiotics in
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active food packaging is scarce, and thus far there is no review article focused solely on this subject. This review highlights the nature of probiotics and their incorporation into
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biopolymer materials intended for active food packaging applications as well as
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legislation related to probiotics.
2. PROBIOTICS: HISTORY, DEFINITION, AND EFFECT ON HUMAN HEALTH
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Ancient civilizations, such as the Greeks and Romans, used fermented dairy foods to maintain health. However, research on microorganisms in fermented food products and their effects on human health have only been studied recently. The history of probiotics started in 1908 when Élie Metchnikoff, Nobel Laureate at the Pasteur Institute, established the relationship between health and longevity with the ingestion of bacteria from yogurt. Dr. Metchnikoff proposed that the bacteria helped control infections caused by enteric pathogens and regulated toxaemia, both of which playing major roles in aging and mortality. This observation resulted in increased yogurt production and consumption (Shah, 2007). The term probiotic has been widely used. According to Hamilton-Miller, Gibson, and Bruck (2003), this term was first used by Lilly and Stillwell in 1965 and referred to
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ACCEPTED MANUSCRIPT observations of in vitro protozoa growth stimulated by other protozoa. During the following decade, the term probiotic was used by Fujii and Cook in 1973 and denoted
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synthetic chemicals in mice that conferred protection against Staphylococcus aureus infection. In 1974, the term was used by Parker in a wider sense to refer to
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microorganism interactions with the animal or human host, i.e. “organisms and
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substances, which contribute to intestinal microbial balance”. Several works concerning
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probiotics have been published since then.
In 2002, FAO/WHO held an expert consultation to evaluate health and nutritional
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properties of probiotics and stablish a definition for probiotics (FAO, 2001). Recently, Wassenaar and Klein (2008) slightly modified the definition to “food or food
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supplements containing defined microorganisms in sufficient numbers to reach the gut
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in viable status resulting in positive health effects after consumption”. The authors claim
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this definition does not contradict the internationally and scientifically accepted definition, although they added qualitative (defined microorganisms) and quantitative (sufficient numbers) requirements to the presumed positive health effects. Probiotic effects are strain specific, thus knowledge of the probiotic genus and species is necessary to obtain the desired effects in the host. The main characteristics of probiotic strains in their relationship with the host are resistance to gastric and bile acid, adherence to mucus or human epithelial cells, antimicrobial activity against pathogenic bacteria, and the ability to reduce pathogen adhesion to surfaces and bile salt hydrolase activity (FAO, 2002). There are several mechanisms by which probiotics may benefit human, including production of antimicrobial substances, strengthening of intestinal barrier, modulation of
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(FAO, 2001; Marco, Pavan, & Kleerebezem, 2006; Parvez, Malik, Ah Kang, & Kim,
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2006).
When probiotic microorganisms are incorporated into foods, they must be able to
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survive through the digestive tract and successfully proliferate in the gut. Thus, they
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must be resistant to gastric juices and be able to grow in the conditions of the intestine. An interesting option is to use a food matrix that protects them and favors their survival.
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Several factors affect the survival of ingested probiotics in the gastrointestinal tract, including stomach acid, bile salt concentrations, time of exposure, and probiotic species
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and strains. However, many probiotics are able to pass through the gastrointestinal tract and enter the colon in viable numbers in order to impart beneficial effects. In this regard,
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recent studies have explored the effect of the food matrix in the survival of probiotic to the conditions of the gastrointestinal tract and their adhesion to intestinal cells. Ranadheera et al. (2010) have deeply reviewed the relationship among probiotic efficacy and food matrices (and their physicochemical properties), indicating that food matrix selection is a key factor that should be considered when developing functional probiotic food. In this context, Ranadheera et al. (2012) have studied the effect of three different food matrices (goat's milk ice cream, plain and fruit yogurts) on probiotic viability of Lactobacillus acidophilus LA5, Bifidobacterium animalis subsp. lactis BB12 and Propionibacterium jensenii 702, finding that, among the tested food matrices, ice cream presented the best potential to ensure probiotic viability in simulated gastrointestinal conditions (acid and bile tolerance), while fruit yogurt matrix allowed the
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ACCEPTED MANUSCRIPT best cell adhesion of probiotics. Also, probiotic survival to food processing conditions has been studied. In this context, Majeed et al. (2016) studied the survival of Bacillus
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coagulans MTCC 5856 in different functional foods, such as banana muffins and waffles
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for up to 12 months, coffee at extreme conditions (90 °C for 2 min and at 77 °C for 4 h), chocolate fudge frosting, hot fudge top-pings, peanut butter, strawberry and vegetable
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oil at room temperature up to 12 months. As a result, B. coagulans MTCC 5856 showed
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potential to be used as probiotic when developing innovative functional food products due to its stability towards processing and storage condition of tested food.
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Although there is no consensus among the international scientific community about effective probiotic doses to achieve health effects, researchers have suggested
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minimum doses between 106 and 109 CFU·d-1 to ensure therapeutic effects (Espírito Santo, Perego, Converti, & Oliveira, 2011).
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Fermented dairy products are considered good carriers for probiotic microorganisms. Other food matrices, such as fruits and vegetables, are considered potential carriers for these microorganisms because of the increasing lactose intolerance and vegetarianism among consumers (Martins et al., 2013). Besides presenting beneficial health effects, probiotic microorganisms have also been related to effects against other (undesirable) microorganisms when inoculated into foods. In this regard, Alegre, Viñas, Usall, Anguera, and Abadias (2011) tested the antimicrobial activity of a probiotic culture (Lactobacillus rhamnosus GG) against two pathogens – Salmonella and L. monocytogenes. Fresh-cut apple wedges were immersed in solutions containing the probiotic bacteria (10 8 CFU·mL−1) and/or the pathogens (105 CFU·mL−1), placed in polypropylene trays and sealed with a
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presence of the probiotic. The probiotic viability was maintained above recommended
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levels (106 CFU·g-1) until 14 days of storage at 5 °C. Moreover, Fernandes et al. (2013) developed a dairy dessert incorporated with Lactobacillus acidophilus LA-5 as a
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probiotic microorganism and tested its antimicrobial activity against L. innocua by
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means of three formulations (F1: inoculated with L. acidophilus LA-5; F2: inoculated with L. innocua; F3: inoculated with both L. innocua and L. acidophilus LA-5). Differently
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from the results observed by Alegre et al. (2011), the findings by that study showed that the count of the probiotic microorganism diminished while studying product shelf life in
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formulation F1. Also, no antimicrobial effect was observed against L. innocua. In this regard, population of L. innocua increased in formulations F2 and F3, indicating a
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mutual benefit and positive growth effect among the tested probiotic and the target pathogen microorganisms. Similarly, Jesus et al. (2016) studied the interaction of Listeria monocytogenes and probiotic microorganisms (Lactobacillus acidophilus and Bifidobacterium lactis). They reported that L. monocytogenes can growth in probiotic cottage cheese in both condition, when product is submitted to adequate storage conditions (4 °C/ 28 days), as well as in situations of temperature abuse (30% of the shelf life at 4 °C and the remaining 70% at 12 °C). Therefore, microbiological quality of food products incorporated with probiotic microorganisms should not rely on the protective effect of probiotic cultures but on the use of proper hygienic processing conditions and on the excellent microbiological quality of raw materials used.
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3. PROBIOTICS IN ACTIVE/BIOACTIVE EDIBLE FILMS AND COATINGS
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For probiotics to play the intended role in human health, it is essential that both viability
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and the metabolic activity are maintained throughout food processing and supply chain, as well as within human gastrointestinal tract. Several methods have been tested to
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increase the quality of probiotic cultures, including exposure to sub-lethal heat or cold
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stress, osmotic stress, low pH, and reduced redox potential (e.g. through the use of oxygen scavengers, oxygen-consuming microorganisms, and modified atmosphere
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packaging) (Nguyen, Truong, Kouhoundé, Ly, Razafindralambo, & Delvigne, 2016); however, microencapsulation is by far the most exploited approach. When combined,
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microencapsulation and active edible packaging concepts denote a promising strategy
3.1.
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for protecting and delivering probiotic species efficiently.
Microencapsulation of probiotics
Microencapsulation may be defined as the process of packing functional compounds (e.g. probiotic culture) into microcapsules made up of an encapsulant material (da Silva, Barreira, & Oliveira, 2016). When applied to probiotics, microencapsulation techniques are intended to carry and protect them from the detrimental action of pH, oxygen, and light, to mention a few. Therefore, this process can diminish probiotic reactivity to the environment and prevent its degradation, besides masking unpleasant flavors and odors (da Silva et al., 2016). The encapsulation protocols are various, including spray drying (Li et al., 2016; Ranadheera, Evans, Adams, & Baines, 2015), high-voltage electrospinning/electrospraying (Coghetto, Brinques, Siqueira, Pletsch, Soares, & Ayub,
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coacervation, and emulsion (Krasaekoopt, 2013). Probiotic encapsulation methods have
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been extensively reviewed elsewhere (de Prisco & Mauriello, 2016; Martín, LaraVilloslada, Ruiz, & Morales, 2015).
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Microencapsulation has been combined to active packaging as an alternative means of
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incorporating probiotics. Probiotic microencapsulation stands out as a promising alternative for applying those microorganisms and replacing antibiotics, since this
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process allows the gradual release of compounds of interest in order to preserve the food (Favaro-Trindade, Pinho, & Rocha, 2008; Mirzaei, Pourjafar, & Homayouni, 2012).
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Thus, studies on the development of active food packaging featuring probiotic microorganism action are worthwhile despite the challenges involved in the
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encapsulation technique itself. Regarding the microencapsulation process, suitable encapsulating materials have been extensively studied, especially biodegradable polymers that can be also applied for active food packaging production. These include alginate (Etchepare et al., 2015; Sohail, Turner, Coombes, Bostrom, & Bhandari, 2011), acetate (Fávaro-Trindade & Grosso, 2002), chitosan (Krasaekoopt, Bhandari, & Deeth, 2003), carboxymethyl cellulose (CMC), protein (Guérin, Vuillemard, & Subirade, 2003; Vonasek, Le, & Nitin, 2014), carrageenan, gelatin, and pectin (Burey, Bhandari, Howes, & Gidley, 2009; Favaro-Trindade et al., 2008; Li et al., 2009). Altamirano-Fortoul, Moreno-Terrazas, Quezada-Gallo, and Rosell (2012) used the combination of microencapsulation and starch-based coatings to incorporate Lactobacillus acidophilus. Those authors coated the surface of partially baked breads with a film-forming solution
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ACCEPTED MANUSCRIPT incorporated with L. acidophilus. According to Altamirano-Fortoul et al. (2012), L. acidophilus remained stable after the baking procedure, presenting counts of 10 7
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CFU·bread-1. Thus, L. acidophilus can be used on bread surfaces by means of microcapsules incorporated in edible coatings, resulting in bread with additional health
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benefits provided by probiotics. L. rhamnosus GG has also been encapsulated in
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hydrogel beads comprising pectin, glucose, and calcium chloride (Li, Zhang, Polk,
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Tomasula, Yan, & Liu, 2016). Moreover, probiotics may also be encapsulated directly into food matrices. In this regard, a mixture of L. acidophilus LA5, Bifidobacterium subsp.
lactis
BB12,
and
Propionibacterium
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animalis
jensenii
702
was
microencapsulated into goats‟ milk (Ranadheera et al., 2015). As a result, the probiotics
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submitted to the encapsulation process maintained satisfactory viable levels (10 6-108 cfu/g); on the other hand, storage conditions at 30 °C after processing reduced
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significantly their viability, while lactobacilli and propionibacteria were not affected when stored at 4 °C.
3.2.
Probiotic edible films and coatings
Increased consumer interest in health, nutrition, food safety, and environmental issues has led to improved research on the film-forming properties of biopolymers to produce edible films for food packaging (Espitia, Du, Avena-Bustillos, Soares, & McHugh, 2013). Although edible films and coatings do not replace an external packaging – which is usually non-biodegradable and, for most probiotic bacteria, must act as a good barrier to oxygen (da Cruz, Faria, & Van Dender, 2007) –, they help packaging in its food protecting function, since they reduce the rates of moisture and gas transfer between
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ACCEPTED MANUSCRIPT food and the surrounding environment, contributing to extend food stability. Edible films may thus reduce the required amount of packaging for each application, reducing the
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negative environmental impact caused by the discard of non-biodegradable materials.
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Apart from their passive protecting function, edible films and coatings may also play some active or bioactive roles.
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The concepts of active and bioactive packaging have been sometimes used
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indiscriminately, but there are differences. Active food packaging systems are those which go beyond the traditional passive role of food protection and include desirable
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interactions with the food, in a way that is relevant to extend food stability; a typical active packaging is antimicrobial packaging, which interacts with the product or the
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headspace inside to decrease, prevent or delay microbial growth on food surfaces (Soares et al., 2009). In previous studies, biopolymers have been used to carry natural
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antimicrobial compounds such as essential oils (Botrel, Soares, Espitia, Sousa, & Renhe, 2010; Espitia, Soares, Botti, & Silva, 2011; Otoni, Avena-Bustillos, Olsen, Bilbao-Sáinz, & McHugh, 2016; Tripathi & Dubey, 2004), organic acids (Schirmer et al., 2009), enzymes (e.g. lysozyme) (Appendini & Hotchkiss, 1997), and bacteriocins (Espitia, Otoni, & Soares, 2016; Gálvez, Abriouel, López, & Omar, 2007; Han, 2005). Active food packaging has been developed in response to consumer demand for safer and less processed food with extended shelf-life (Ahvenainen, 2003). Bioactive food packaging systems, on the other hand, are those which may contribute to health benefits to the consumers (Lopez-Rubio, Gavara, & Lagaron, 2006). It is a novel approach of the concept of functional foods, which proposes that any food that may provide a health benefit beyond the traditional nutrients it contains may be considered
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specific case of edible bioactive films and coatings, this release is not even required,
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since the film/coating itself is supposed to be eaten with the food. Bioactive packaging has been reviewed elsewhere (Lopez-Rubio et al., 2006).
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The incorporation of probiotic cultures into edible coatings was first proposed in 2007 by
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Tapia et al. (2007). Thus, research on the development of films and coatings incorporated with probiotics intended as active food packaging is still emerging, with a
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limited number of studies. Edible films and coatings may be regarded as feasible alternatives for carrying and delivering probiotics. Considering that packaging materials
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containing probiotics may enhance food stability (by controlling the growth of spoilage microorganisms by competition) and also contribute to the health of consumers, they
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may be considered both as active and potentially bioactive materials. The main features of the studies on films and coatings containing probiotics are summarized in Table 2.
3.2.1. Studies focused on probiotic viability in films Traditionally, the systems intended to deliver probiotic cultures have both a conventional (pharmaceutical-related products) and a non-conventional (e.g. food-based products) approach (da Silva et al., 2016). Active edible films and coatings may present both aspects as their intake may be expected alongside a regular food product or they may act as exclusively a carrier instead, such as in oral-disintegrating films. Regardless of the mechanism, the major role (i.e. delivering health benefits) of probiotic-containing edible films and coating is played more or less efficiently depending upon their ability to
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ACCEPTED MANUSCRIPT provide viable bacteria to the gastrointestinal tract. The viability, stability, and survival of several probiotic strains under various conditions has been extensively investigated and
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reviewed (Corona-Hernandez, Álvarez-Parrilla, Lizardi-Mendoza, Islas-Rubio, de la
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Rosa, & Wall-Medrano, 2013; Dianawati, Mishra, & Shah, 2016; Paseephol & Sherkat, 2009; Ranadheera et al., 2015; Vinderola, Binetti, Burns, & Reinheimer, 2011). Fewer
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though meaningful studies have focused on evaluating the viability of probiotic strains
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specifically in films in order to assess their stability in terms of active/bioactive properties. These are further discussed in this section.
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Pullulan and various starches (from potato, tapioca, and corn) have been used to develop novel edible films incorporated with a mix of probiotic cultures (Lactobacillus
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reuteri ATCC 55730, L. rhamnosus GG ATCC 53103, and L. acidophilus DSM 20079)
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at an initial concentration of 12.9 log·CFUmL-1 (Kanmani & Lim, 2013). Treatments were
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tested with films prepared from pure pullulan and mixtures of different starches and pullulan, stored at 25 and 4 °C. The probiotic viability in pure pullulan film was around 80% after 10 days of storage at 25 °C, decreasing to 35% after 20 days. Films incorporated with starches, however, presented decreased cell viability: the higher the starch content, the lower the viability. At 4 °C, on the other hand, the viabilities were higher – near 90% for pullulan and pullulan/potato starch (75:25 weight ratio) films up to 30 days of storage. Prebiotics, which may be defined as “the selectively fermented ingredients that allow specific changes, both in the composition and/or activity in the gastrointestinal microbiota that confers benefits upon host well-being and health” (Gibson, Probert, Loo, Rastall, & Roberfroid, 2004), have also been incorporated into edible films to improve
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ACCEPTED MANUSCRIPT the stability of probiotic strains that had been added to the film-forming dispersions. Romano et al. (2014) prepared methylcellulose (MC) films containing two probiotic
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strains (Lactobacillus delbrueckii subsp. bulgaricus CIDCA 333 and Lactobacillus
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plantarum CIDCA 83114) and fructo-oligosaccharides (FOS) as a prebiotic. The bacterial strains were found to be completely embedded in the film matrix, whose
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integrity was not affected by the presence of these probiotic bacteria. Since FOS were
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found to present not only positive effects (protecting L. delbrueckii) but also negative effects (reducing the glass transition temperature of the films), the FOS concentrations
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were selected according to a balance between those effects. Films containing L. delbrueckii were then added with 3% (w/v) of FOS, while films with L. plantarum were
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added with 1% of FOS. L. plantarum was found to be stable for longer periods at higher RH values, when compared to L. delbrueckii, which may be useful for practical
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applications. Similarly, inulin, chitosan oligosaccharide (COS), galacto-oligosaccharide (GtOS) and FOS have been added to maize starch-based edible films for prebiotic purposes and have been shown to promote the growth of the probiotic bacteria Bifidobacterium infantis ATCC 15697 and Lactobacillus fermentum ATCC 9398 (Tang et al., 2015). In addition to the prebiotic effect, these compounds have also affected the physical properties of the edible films, which have shown impaired tensile strength and boosted extensibility when compared to prebiotic-free (control) films. According to the authors, this plasticization effect may be attributed to the much smaller molecular weights of the prebiotics than that of starch. Soukoulis, Behboudi-Jobbehdar, Yonekura, Parmenter, and Fisk (2014) developed gelatin films containing L. rhamnosus GG and four selected prebiotic components:
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ACCEPTED MANUSCRIPT inulin, polydextrose, gluco-oligosaccharides (GOS), and wheat dextrin. The prebiotics made the film structure more uniform. GOS were reported as the prebiotic that provided
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the best protection to the probiotic during film drying at 37 °C, allowing the retention of
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60% of cells, followed by polydextrose, which allowed 26% cell retention during drying. Surprisingly, inulin and wheat dextrin presented a negative effect on bacterial survival.
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On the other hand, inulin was the most effective prebiotic agent to protect the probiotic
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during storage; while it took 63–83 days for the films with other prebiotics to have their probiotic population reduced by 1 log cycle, the same reduction occurred after 100 days
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for the film with inulin.
Starch (from rice and corn)-protein (bovine gelatin, sodium caseinate, and soy protein)
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edible films were added by L. rhamnosus GG and stored at fridge and room temperature (Soukoulis, Singh, Macnaughtan, Parmenter, & Fisk, 2016). Both storage
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temperature and film composition were found to play a significant role in the viability and stability of the probiotic culture during the film-forming procedure as well as throughout storage. The loss of L. rhamnosus GG cells induced by film processing (i.e. solvent evaporation), for instance, was significantly lower in protein-based films than in their starch-based counterparts. Furthermore, rice starch and proteins were observed to act synergistically as to L. rhamnosus GG viability. Finally, film shelf life (threshold: 6 log viable CFU·g-1) was maintained until 27-96 and 15-24 days when stored at 4 and 25 °C, respectively (Soukoulis et al., 2016). Piermaria, Diosma, Aquino, Garrote, and Abraham (2015) incorporated L. plantarum and Kluyveromyces marxianus cells into glycerol-plasticized edible kefiran (a polysaccharide produced by lactic acid bacteria) films. While the authors demonstrated
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ACCEPTED MANUSCRIPT that the physical and optical properties of the films were nearly unchanged upon the addition of the probiotic cultures, the high susceptibility of the latter to acid was reduced
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by its inclusion into the polymer matrix. The film-forming procedure (casting at 37 °C)
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led to a slight decrease in the L. plantarum count, whereas that of the yeast remained constant. Furthermore, the viability of both microorganisms was maintained throughout
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storage at non-refrigerated temperature.
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Coatings based on sodium alginate or alginate/whey protein concentrate (WPC) containing L. rhamnosus GG have been applied by Soukoulis, Yonekura et al. (2014) to
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bread, which was then air dried at 60 °C for 10 min or 180 °C for 2 min. The alginate/WPC coating resulted in higher viability of the probiotic strain throughout drying
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(76.3%) when compared to the alginate coating (15.9%), while the drying regime did not significantly affect the viability. The cell viability was considerably reduced during the
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initial 24 h of storage, then stabilized, and finally increased upon days 4-7 of storage. Differently from most other studies, this one included an in vitro digestion test for evaluating probiotic viability, and also defined the amount of probiotics to be delivered with a certain amount of food. Coated bread crust samples were submitted to in vitro digestion under simulated gastrointestinal conditions; the sample coated with alginate resulted in a lower viability loss (0.7 log CFU·g-1) than the sample coated with alginate/WPC (1.5–1.6 log CFU·g-1), that is to say, the alginate coating provided higher protection than alginate/WPC coating upon in vitro digestion. The probiotic level to be delivered by a bread slice (30–40 g) was calculated as being 7.6–9 log CFU (before digestion) and 6.5–6.9 log CFU (after in vitro digestion), meeting the required cell counts for the bread to be considered as probiotic.
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3.2.2. Studies focused on inhibitory activity against other microbial species
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Tapia et al. (2007) applied alginate and gellan edible coatings incorporated with B. lactis
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BB-12 on fresh-cut fruits (apple and papaya cylinders). Alginate or gellan film-forming solutions (2% w/v) incorporated with viable bifidobacteria were applied on the surface of
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the fresh-cut fruits. The results showed that, even if the counting of B. lactis Bb-12 in
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coatings usually decreased significantly upon 10 days of storage at 2 °C (with viability losses of up to 85%), it was still greater than 106 CFU·g-1 after 10 days. These results
a viable manner on fresh-cut fruits.
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indicated that alginate and gellan are able to carry and hold probiotic microorganisms in
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Gialamas, Zinoviadou, Biliaderis, and Koutsoumanis (2010) developed edible films from sodium caseinate incorporated with Lactobacillus sakei cells. Two techniques were
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used to add the probiotic strain into the caseinate matrix – i.e. direct incorporation to the film-forming solution or spraying on a pre-formed film. The films were applied to the surface of both a laboratory medium (tryptose soy agar, TSA) and a food model system (fresh beef) previously inoculated with L. monocytogenes. After the contact of the film with the surface of TSA at 4 °C, the population of L. sakei grew rapidly, from an initial population of less than 106 to 107 CFU·cm-2 within 4 days, regardless of the L. sakei addition technique. After 12 days of storage, films containing L. sakei presented a pathogen population decreased by 3 log cycles (in the case of films obtained from the probiotic-containing film-forming solution) or 3.6 log cycles (in the case of the sprayed film). The L. monocytogenes level in fresh beef packed in films containing L. sakei and stored at 4 °C was reduced by 2 log cycles when compared to the samples with the
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ACCEPTED MANUSCRIPT control film (without L. sakei). The counting of L. sakei was maintained above 106 CFU·cm-2 of film area for at least 21 days at 4 °C. Interestingly, sorbitol (used as a film
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plasticizer) was found to improve the viability of L. sakei, corroborating the role of
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polyols as protective agents for microbial cells upon storage at low water activity (Linders, de Jong, Meerdink, & van't Riet, 1997). Some mechanisms have been
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proposed to explain these protective effects, such as lowering the phase transition
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temperature of dry membranes, maintaining the membrane fluidity, and protecting the protein structure in dry state (Leslie, Israeli, Lighthart, Crowe, & Crowe, 1995;
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Santivarangkna, Naumann, Kulozik, & Foerst, 2010). Carnobacterium maltaromaticum is considered as a potential probiotic microorganism
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(Lauzon et al. 2014), commonly found in several fish species as part of their normal intestinal flora. C. maltaromaticum isolated from rainbow trout (Oncorhynchus mykiss)
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presented activity against Gram-positive and Gram-negative pathogens, as well as a broad spectrum of antibiotic resistance (Kim & Austin, 2008). Concha-Meyer, Schöbitz, Brito, and Fuentes (2011) developed a film based on alginate incorporated with viable C. maltaromaticum to preserve smoked salmon at refrigeration temperatures. The films were applied on the surface of smoked salmon pieces and presented bacteriostatic effect against L. monocytogenes – which had been previously inoculated to a final concentration of 104 CFU·cm-2 – over 28 days at 4 °C. The authors indicated that these results exceed the industrial shelf-life requirements for smoked salmon, demonstrating that the developed films inhibited L. monocytogenes on salmon under specified conditions.
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ACCEPTED MANUSCRIPT The probiotic bacteria L. acidophilus and Bifidobacterium bifidum were inoculated into edible gelatin coatings and films for preserving hake fish (Merluccius merluccius) (López
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de Lacey, López-Caballero, Gómez-Estaca, Gómez-Guillén, & Montero, 2012). The counts of L. acidophilus and B. bifidum, both on film-forming solutions and films
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presented an initial concentration of 109 CFU·mL-1, with both probiotic cultures
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remaining constant for 6 days at 2 °C. The application of gelatin coatings (with or
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without B. bifidum) to hake cuts resulted in a significant reduction of the population of H2S-producing microorganisms, presumably Shewanella putrefaciens, when compared
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to the uncoated hake. Thus, the study was not conclusive about whether the reduction in the growth of H2S-producing microorganisms resulted from an inhibitory effect from
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the probiotic bacteria or from the coating itself. In a second step of the study, hake wrapped with films were submitted to a low-level high pressure treatment (200 MPa for
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10 min at 20 °C), in order to reduce the Gram-negative flora while affecting less the Gram-positive bacteria (including those incorporated in the film), and also to avoid sensory changes of fish. The counts of total bacteria and H2S producers were reduced by the high pressure treatment, while both counts of lactic acid bacteria and bifidobacteria were unaffected by it. The results suggest that the combination of edible films containing bifidobacteria with a high pressure treatment is promising for the preservation of fish and other products whose spoilage is determined by Gram-negative bacteria. The same group conducted another study (López de Lacey, López-Caballero, & Montero, 2014) incorporating green tea extract and two probiotic strains (Lactobacillus paracasei L26 and B. lactis B94) into agar-based films that were then applied to hake
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ACCEPTED MANUSCRIPT fillets previously inoculated with S. putrefaciens and Photobacterium phosphoreum (103–104 CFU·g-1). The probiotic bacteria migrated to the fish, resulting in proliferation of
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lactic acid bacterial populations. The films containing probiotics and/or green tea extract
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resulted in decreased chemical spoilage indicators (total volatile bases and trimethylamine nitrogen, and pH changes) and reduced counts of H 2S-producing
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microorganisms, when compared to hake coated with a film without those agents or
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uncoated hake. The combination of probiotics with green tea extract in films resulted in better chemical and microbial stabilities when compared to films containing just
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probiotics, leading to a shelf-life extension of at least a week. Different biopolymers, such as sodium caseinate, pea protein, MC and hydroxypropyl
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methylcellulose (HPMC), have been tested for incorporating L. plantarum in edible films based on polysaccharide or protein (Sánchez-González, Quintero Saavedra, & Chiralt,
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2013). According to Sánchez-González et al. (2013), protein-based films allowed higher L. plantarum viability, with bacteriocin production being slower than in cellulose-based films, which in turn presented higher bacteriocin production. In addition, HPMC and MC films incorporated with L. plantarum completely inhibited Listeria innocua growth during the first 8 days of storage at 5 °C, indicating that these films were effective carriers of L. plantarum. Sodium caseinate and MC have been used to develop biopolymeric films incorporated with L. acidophilus and L. reuteri (Sánchez-González, Quintero Saavedra, & Chiralt, 2014). The survival of both probiotic cultures in biopolymeric films and their antimicrobial potential against L. innocua were assessed. Sánchez-González et al. (2014) reported that the viability of L. acidophilus was greater than that of L. reuteri in
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ACCEPTED MANUSCRIPT both polymeric matrices. L. reuteri presented a significant reduction of its initial population during the first week of storage, indicating that this strain is more sensitive to
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the stress suffered during storage. Moreover, when comparing both hydrocolloid matrices, sodium caseinate was a more favorable environment than MC for
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microorganism survival, reaching viability on the order of 10 7 CFU·cm-2 after 3 days of
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storage. With regard to the antilisterial activity, the best results were obtained with MC
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films after 3 days of storage. No differences were observed among the different films after a longer storage time, though L. innocua growth was reduced by approximately 1.5
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log cycles compared to the control after 12 days of storage.
applications
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3.3 Food matrix consideration and potential for probiotic films and coatings
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Traditionally, dairy food products have been used as carriers of probiotic microorganisms. Recently, other food matrices with a different origin have been tested with the same purpose, such as meat, traditional cereal-based beverages and chocolate (Figure 3).
The physicochemical as well as functional properties of these food matrices have a key role in ensuring probiotic viability. In this regard, Ranadheera et al. (2010) have indicated that food formulation can be used to favor probiotic viability, with concentration of fat, protein, carbohydrates and their interactions as the main factors that support probiotic microbial growth. Thus, properly formulated food can be an effective carrier of probiotic by two means:
Direct probiotic delivery through the formulated food matrix;
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Indirect probiotic delivery, when formulated food constitutes the polymeric matrix for packaging material development. In this context, the developed packaging material
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is edible and should present satisfactory conditions for probiotic viability.
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Moreover, food preservation is commonly associated with chemical additive and good manufacturing and storing practices. However, active food packaging incorporated with
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natural compounds has emerged as a potential alternative to chemical preservative for
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food preservation. Previous research studies (Tapia et al. 2007; Gialamas et al. 2010; Concha-Meyer et al. 2011; López de Lacey et al. 2012; López de Lacey et al. 2014;
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Soukoulis et al. 2014b) have shown the potential food that might be preserved by the application of probiotic films and coatings include fish, fresh meat, fruits and baked food
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products, such as bread (Figure 2).
In any case, whether the probiotic is incorporated into the formulated food or into the
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packaging material, the carrier should protect probiotic microorganisms against external factors, as well as the effect of the gastrointestinal and bile conditions (Desobry & Debeaufort (2012).
4. REGULATIONS RELATED TO PROBIOTICS AND ACTIVE FOOD PACKAGING In the United States, regulatory requirements are determined by the intended use of probiotics, whether as a drug or as a dietary supplement. Although probiotics fall into virtually all product categories regulated by the FDA, there is still no pathway to deal specifically with probiotics. Instead, probiotic products are regulated based on the product category into which they fall, such as food or food additive (Hoffmann et al., 2012, reviewed in 2016; U.S. Food and Drug Administration, 2016). For example, only
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ACCEPTED MANUSCRIPT premarket notification is required if the probiotic product is intended to be used as a dietary supplement (Venugopalan, Shriner, & Wong-Beringer, 2010). The probiotic
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product must go through a regulatory process, however, if the probiotic is intended to be
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used as a drug.
Most probiotic microorganisms have a long-lasting history of safe use as food
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components, so safety evaluation does not denote a hurdle to be overcome (van
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Loveren, Sanz, & Salminen, 2012). Among them, numerous microorganisms have been qualified with the presumption of safety (QPS) status for food applications (EFSA, 2010;
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Leuschner et al., 2010) by the European Food Safety Authority (EFSA) and have been
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Administration (FDA, 2016).
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classified as generally regarded as safe (GRAS) by the U.S. Food and Drug
On the other hand, the European legislation is more conservative, as described by
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Miquel et al. (2015) and Glanville, King, Guarner, Hill, & Sanders (2015). The term “probiotic” is not regulated, since the designation implies a beneficial health effect, and should be considered a health claim by itself. On one hand, many microorganisms currently used in food fermentation have a long history of safe use in the European Union (EU). On the other hand, foods containing microorganisms which have not had a traditional use in food production in Europe before 1997 are considered as novel foods, whose legislation is currently under Regulation (EC) No 2015/2283 (European Commission, 2015). A novel food should be subjected to an in-depth characterization and safety assessment should be done before commercialization on the European market. According to the EU legislation on health claims, based on Regulation (EC) No 2006/1924 (European Commission, 2006), the communication of any health claim to
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ACCEPTED MANUSCRIPT consumers (such as categorizing a food product as “probiotic”) may only be made after authorization by the European Commission, which requires a favorable opinion from the
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EFSA. In Brazil, the “Technical regulation of bioactive substances and probiotics isolates with
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alleged of functional or health properties” (RDC No 2/2002 ANVISA) is used as a
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guideline for the safety assessment, registration and commercialization of bioactive
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substances and probiotics with claims of health properties (ANVISA, 2002). However, Brazilian regulation, similar to those of USA and Europe, does not provide a specific law
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5. FINAL CONSIDERATIONS
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for edible materials containing probiotic microorganisms.
The global probiotics market has been constantly growing due to consumer concerns
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regarding healthy diets and wellness. In this context, the consumption of probiotic food products has been constantly increasing. Another trend in food technology is the growing use of edible films and coatings, acting as packaging aids towards extending food stability.
Incorporating probiotics into edible films and coatings has been proposed as an emerging technology which has generated a number of studies in the last decade. The probiotic films and coatings would be considered as bioactive materials, in the sense that they may promote health benefits to the consumer, due to their potential probiotic properties. Concomitantly, probiotic films and coatings may also be considered as active, in the sense that they may promote an active role in extending food stability, which is based on the premise that probiotic bacteria present competitive effects against
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ACCEPTED MANUSCRIPT spoilage microorganisms. However, although the incorporation of probiotic bacteria into an edible material is expected to be primarily motivated by the promotion of health
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benefits to the consumers, those effects have not been approached in those studies.
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Instead, developed studies were focused on either evaluating the viability of the probiotic strains (in order to establish if the films are suitable to keep the probiotics alive
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throughout processing and storage) and/or studying the effects of films or coatings on
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growth of spoiling or pathogenic microorganisms, based on the premise that probiotic bacteria present competitive effects against spoilage bacteria. Just one study
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(Soukoulis, Yonekura, et al., 2014) advanced in evaluating cell viability upon simulated gastrointestinal conditions, and also established the level of probiotic to be delivered by
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a defined portion of the food product. Nevertheless, more studies are required to evaluate two important aspects of any product to be considered as probiotic: (a) the
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ability of probiotic strains contained in edible films or coatings to survive the transit through the upper gastrointestinal tract, and (b) the release of probiotic strains from the matrices to colonize the intestine. Those kinds of information are essential to establish whether the materials may really be regarded as probiotic edible films and coatings, or just active materials with antimicrobial effects to extend food stability.
6. ACKNOWLEDGEMENTS PJP Espitia thanks the National Bureau for the Development of Science and Technology in Colombia (COLCIENCIAS) and Universidad del Atlántico. RA Batista thanks the support provided by National Counsel of Technological and Scientific
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ACCEPTED MANUSCRIPT Development (CNPq). CG Otoni thanks the financial support of São Paulo Research
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Foundation (FAPESP, grant # 2014/23098-9).
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Science & Technology, 50, 144–158. Vinderola, G., Binetti, A., Burns, P., & Reinheimer, J. (2011). Cell viability and
1–6.
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functionality of probiotic bacteria in dairy products. Frontiers in Microbiology, 2,
Vonasek, E., Le, P., & Nitin, N. (2014). Encapsulation of bacteriophages in whey protein films for extended storage and release. Food Hydrocolloids, 37, 7–13. Wassenaar, T. M., & Klein, G. (2008). Safety aspects and implications of regulation of probiotic bacteria in food and food supplements. Journal of Food Protection, 71, 1734–1741.
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ACCEPTED MANUSCRIPT Figure captions Figure 1. Number of publications on probiotics (topic: probiotic*) and on food packaging
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Figure 2. Direct probiotic delivery through the formulated food matrix.
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Figure 3. Indirect probiotic delivery: Potential food to be considered for probiotic films
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Figure 2.
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Figure 3.
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Table 1. Recent studies regarding probiotic applications in food matrices Probiotic Food Research target Reference microorganism matrix Streptococcus thermophiles salivarius spp. TA 040 Evaluation of quality parameters of Lactobacillus delbrueki strawberry probiotic yogurt added with Batista et al spp. bulgaricus LB340 glucose oxidase. To do so, developed 2015 Lactobacillus product was compared with commercial acidophilus La14 probiotic products. Bifidobacterium longum BL05 Streptococcus thermophilus TA040 Lactobacillus delbrueckii ssp. Incorporation of glucose oxidase in Cruz et al bulgaricus LB340 increasing levels and its effect in the 2012 Yogurt Bifidobacterium developed final product. longum BL05 Lactobacillus acidophilus LA14 Lactobacillus acidophilus LA5 Assessment of the viability of tested Bifidobacterium probiotic microorganisms in plain and Ranadheera animalis subsp. lactis stirred fruit yogurts based on goats‟ milk, et al 2012 BB12 as well as product characteristics Propionibacterium (physicochemical and sensorial). jensenii 702 Streptococcus thermophiles Evaluation of the physicochemical Balthazar et Lactobacillus parameters of sheep yogurt containing al 2016 delbrueckii ssp. inulin at different concentrations. bulgaricus Lactobacillus Evaluation of the efficiency of two different acidophilus LA14 Yogurt probiotic matrices on the immune system Lollo et al Bifidobacterium and whey in Wistar rats exercised to the point of 2013 longum BL05 beverage exhaustion after receiving the developed products for 14d. Streptococcus Evaluation of the efficiency of the salivarius thermophilus developed product submitted to ultra-high ssp. TA040 temperature and dynamic high pressure in Lollo et al Fermented maintaining the immune system of rats Lactobacillus 2015-2 milk acidophilus NFCM exercised to exhaustion after receiving the product for 14d. Streptococcus Determination of the influence of dynamic Oliveira et high pressure on the probiotic developed 52
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al 2014
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Development of a fermented dairy drink based on goats‟ milk and incorporated with Lactobacillus acidophilus LA5, Fermented Bifidobacterium animalis subsp. lactis dairy drink Ranadheera BB12 and Propionibacterium jensenii 702, made from et al. 2016 alone or in combination; and goats‟ milk determination of main developed product characteristics (microbial, physicochemical, and sensorial). Evaluation of the L. casei Zhang incorporation on main characteristics Dantas et al (physicochemical, optical, rheological and 2016 sensorial) of the developed product. Determination of the sodium reduction and Felicio et al arginine incorporation effect on quality 2016 parameters of the developed product. Assessment of increasing concentration of probiotic microorganisms on Gomes et al Minas physicochemical parameters and sensory 2011 fresh acceptance of developed product. cheese Evaluation of key parameters of the immune system of Wistar rats that were Lollo et al submitted to acute, intense physical 2012 exercise after receiving a diet with the developed product for 14d. Assessment of the effect of developed product consumption on arterial Lollo et al hypertension parameters while tested in 2015 spontaneous hypertensive rats (SHRs, 7 weeks old). Assessment of the ideal sucrose concentration and other sweeteners (stevia, sucralose, aspartame, and Esmerino et Neotame on the viability of the starter and al 2013 Petit probiotic cultures while incorporated in the Suisse developed product. cheese Estimation of the optimum sucrose concentration and predictions of optimum Esmerino et sucrose level based on acceptance testing al 2015 of the developed product.
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Probiotic microorganism thermophilus TA40 Lactobacillus acidophilus NFCM® Lactobacillus acidophilus LA5 Bifidobacterium animalis subsp. lactis BB12 Propionibacterium jensenii 702
Lactobacillus acidophilus LA14 Bifidobacterium longum BL05 Lactobacillus acidophilus LA14 Bifidobacterium longum BL05
Lactobacillus acidophilus LA14 Bifidobacterium lactis BL04
Lactobacillus acidophilus Bifidobacterium lactis
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Research target
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Evaluation of the effect of antioxidants compounds on the physicochemical, rheological and sensory characteristics of developed product.
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Assessment of the performance of the jabuticaba skin extract in minimizing the oxidative stress in the developed product.
Reference
Pereira et al 2016
Pereira et al 2016-2
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Probiotic microorganism Lactobacillus acidophilus LAC4 Bifidobacterium animalis ssp. lactis DN173–010 Lactobacillus acidophilus LAC4 Bifidobacterium animalis sub sp. lactis DN173-010
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ACCEPTED MANUSCRIPT Table 2. Bioactive films and coatings containing probiotic bacteria Viability
B. lactis Bb12
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Coatings on fresh-cut apples and papayas
> 6 log cycles CFU·g up to 10 days at 2 °C
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Films on fresh beef
> 6 log cycles CFU·cm up to 21 days at 4 °C
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L. sakei
> 7 log cycles CFU·cm up to 28 days at 4 °C
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C. maltaromati cum L. acidophilus B. bifidum
Films on smoked salmon Films and coatings on hake fish
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Green tea extract
Films on hake fillets
Methylcellulo se
L. delbrueckii L. plantarum
Prebiotic: FOS
Films, no substrate
Pullulan Pullulan/starc h blends
L. rhamnosus,, L. reuteri, L. acidophilus
Alginate Alginate/whe y protein concentrate Hydroxyprop yl methylcellulo se Isolate pea protein Methylcellulo se Sodium caseinate Methylcellulo se (MC)
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L. paracasei B. lactis
Films, no substrate
> 8 log cycles CFU·g up to 6 days at 2°C
> 6 log cycles CFU·cm up to 15 days at 4 °C
-2
Time for 1 log reduction (11% RH, 4 °C): L. delbrueckii, 45 days; L. plantarum, 90 days Highest viabilities for pullulan and pullulan/potato starch (75:25): near 90% viability up to 30 days at 4 °C.
Films, no substrate
Time for 1 log reduction (4 °C): 63 days (glucooligosaccharides) to 100 days (inulin)
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Coatings on bread
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L. monocytog enes L. monocytog enes
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L. plantarum
L. reuteri L.
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(d)
H2Sproducing microorgan isms
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(f)
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(g)
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(h)
> 10 CFU·g up to 7 days at room temperature.
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(i)
Glycerol
Films, no substrate
Highest viabilities for 5 sodium caseinate: > 10 -2 CFU·cm up to 30 days at 5 °C.
L. innocua
(j)
Glycerol
Films, no substrate
Highest viabilities for L. 4 Acidophilus: > 10
L. innocua
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L. rhamnosus
Refere nce*
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Prebiotics: inulin, polydextro se, glucoseoligosacch arides, wheat dextrin
L. rhamnosus
Inhibition of other species -1
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Alginate
Other additives
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Biopolymeri c matrix
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(sodium caseinate) and 3 -2 > 10 (MC) CFU·cm up to 30 days at 5 °C. *Cited references: (a): Tapia et al. (2007); (b): Gialamas et al. (2010); (c) Concha-Meyer et al. (2011); (d) López de Lacey et al. (2012); (e) López de Lacey et al. (2014); (f) Romano et al. (2014); (g) Kanmani and Lin (2013); (h) Soukoulis et al. (2014a); (i) Soukoulis et al. (2014b); (j) Sánchez-González et al. (2013); (k) Sánchez-González et al. (2014).
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Graphical abstract
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Highlights
Researchers have been developing new food products containing probiotics
Probiotics are incorporated into polymeric matrices for food packaging purposes
Edible films and coatings incorporated with probiotics are reviewed
Probiotic food packaging is an alternative for controlling foodborne pathogens
Probiotic packaging improves food safety and provides health benefits
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